Vacuum loadlock ultraviolet bake for plasma etch

ABSTRACT

An improved vacuum plasma etching device for plasma etching semiconductor wafers that have a photo-resist pattern. The improved plasma etching device has a reaction chamber in which the plasma etching is performed during a process cycle, an entrance vacuum loadlock for holding the next semiconductor wafer to be plasma etched, an exit vacuum loadlock for transporting the semiconductor wafers out of the reaction chamber after the plasma etching process, and a source of ultraviolet light. Exposing the semiconductor wafer to the ultraviolet light cures the photo-resist patterns, thereby improving CD dispersion, enhancing pattern transfer, and preventing photo-resist reticulation. Curing the photo-resist patterns while the semiconductor wafer is being held during the process cycle in the entrance vacuum loadlock, increases efficiency and productivity.

This application is a division of prior U.S. patent application Ser. No.09/300,095 filed on Apr. 27, 1999 now U.S. Pat. No. 6,339,028.

BACKGROUND ART

1. Field of the Invention

The present invention relates to vacuum plasma etching devices in whichsemiconductor wafers having photo-resist patterns are exposed to avacuum plasma etching process to etch integrated circuits (“IC”) intothe semiconductor wafers. More particularly, the present inventionrelates to a vacuum plasma etching device and a method for curing thephoto-resist patterns with an ultraviolet bake prior to the plasmaetching process to improve CD dispersion, enhance pattern transfer, andprevent photo-resist reticulation.

2. Description of Related Art

Vacuum plasma etching systems and devices for etching high-density IC'sonto semiconductor wafers prepared with a photo-resist pattern are wellknown in the art. These semiconductor wafers, or substrates, aretypically made of silicon. It is common to dispose a layer of metallicmaterial on top of the semiconductor wafer, into which various elements,such as interconnect lines, holes for vertical interconnect lines, vias,and contacts are lithographically transferred. These interconnectingelements are etched to form the components of the desired IC, such astransistors. The photo-resist patterns define where the plasma will etchaway the metallic films.

A typical example of a vacuum plasma etching device is the poly etchdevice sold by Lam Research of Fremont, Calif., under model number 4420.In such a device, an individual semiconductor wafer is taken from aloading cassette of unetched semiconductor wafers, fed into an entrancevacuum loadlock that is pumped down to a vacuum, passed into a vacuumreaction chamber where the plasma etching process takes place, passedinto an exit vacuum loadlock where the vacuum is released, and then fedinto a finished cassette of etched semiconductor wafers. Although thetotal elapsed time, from taking an unetched semiconductor wafer out ofthe loading cassette to placing the etched semiconductor wafer into thefinished cassette, varies, the time required for the plasma etchingprocess within the vacuum reaction chamber usually takes more than 60seconds. Thus, there is a process cycle of at least 60 seconds. Duringthis process cycle the next semiconductor wafer to be etched is heldwithin the entrance vacuum loadlock. Although a portion of this time isused to pump the entrance loadlock down to a vacuum, for the majority ofthe process cycle, the semiconductor wafer sits idly in a vacuum in theentrance vacuum loadlock.

Prior to performing the plasma etching process on the semiconductorwafers, it is desirable to expose the semiconductor wafers toultraviolet light to “cure” the photo-resist pattern. Normally, this isdone in a separate device than the vacuum plasma etching device. Thisultraviolet curing process makes the resist pattern more resistant tothe plasma etch and helps preserve the pattern integrity during theplasma etching process. The presence of a vacuum during this curingprocess helps to remove volatile substances present in the photo-resist,thereby further “hardening” the photo-resist against the plasma etchingprocess. Curing the photo-resist pattern with ultraviolet light improvesCD dispersion, enhances pattern transfer, and prevents photo-resistreticulation.

Despite these advances in the art, there is a need for a plasma etchingdevice that increases efficiency, increases productivity, improves CDdispersion, enhances pattern transfer, and prevents photo-resistreticulation. There is a need for an improved plasma etching device thatnot only performs a vacuum plasma etching process on a semiconductorwafer, but which can also perform an ultraviolet bake on thesemiconductor wafer prior to the plasma etching process to cure thephoto-resist pattern on the semiconductor wafer.

BRIEF SUMMARY OF THE INVENTION

A principle advantage of the present invention is that the unused timein which a semiconductor wafer is held within a vacuum plasma etchingtool loadlock prior to being plasma etched can be efficiently used tocure the photo-resist pattern on the semiconductor wafer by selectivelyexposing the photo-resist pattern to ultraviolet light. The device andmethod of the present invention exposes the photo-resist pattern toultraviolet light and cures the photo-resist pattern, thereby improvingCD dispersion, enhancing pattern transfer, and preventing photoresistreticulation.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features believed characteristic of the invention are setforth in the appended claims. The invention itself however, as well as apreferred mode of use, and further objects and advantages thereof, willbest be understood by reference to the following detailed description ofan illustrative embodiment when read in conjunction with theaccompanying drawings, wherein:

FIG. 1 is an exploded view of a prior-art vacuum plasma etching device;

FIG. 2 is an exploded view of a prior-art vacuum loadlock for theprior-art vacuum plasma etching device of FIG. 1;

FIG. 3 is a side view of a vacuum loadlock of an improved vacuum plasmaetching device according to the present invention; and

FIG. 4 is a top view of the vacuum loadlock of FIG. 3.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring, to FIG. 1 in the drawings, a prior-art vacuum plasma etchingdevice 11 for etching individual semiconductor wafers is illustrated inan exploded view. Vacuum plasma etching device 11 is supported by aframe 13. A user interface panel 15 for data input and operationalmonitoring is carried by frame 13. Vacuum plasma etching device 11includes various other components, including: power sources andregulators, cassettes for holding and transporting multiplesemiconductor wafers, elevator assemblies for moving individualsemiconductor wafers, IC boards for connecting and controlling thevarious components, temperature control mechanisms for maintainingappropriate operating temperatures, sealing devices for maintainingappropriate pressure levels, and pumping mechanisms for producingvacuums in certain chambers.

Of particular importance in prior-art vacuum plasma etching device 11are vacuum loadlock, or entrance loadlock 17, reaction chamber 19,vacuum loadlock, or exit loadlock 21, and vacuum pump 23. Entranceloadlock 17 is coupled to frame 13 and is adapted to receive anindividual, pre-process semiconductor wafer, or simply, pre-processwafer 18, having an upper surface 18 a and a lower surface 18 b (seeFIG. 3). Upper surface 18 a contains a photo-resist pattern (not shown)for defining material that will be etched away during a plasma etchingprocess. Exit loadlock 21 is coupled to frame 13 and adapted to receivean individual, post-process semiconductor wafer, or simply, post-processwafer (not shown). Entrance loadlock 17 and exit loadlock 21 are both influid communication with reaction chamber 19, such that pre-processwafers 18 may be moved from entrance loadlock 17 to reaction chamber 19,and that the post-process wafers may be moved from reaction chamber 19to exit loadlock 21. Vacuum pump 23 is carried by frame 13, and is apressure regulating device. Vacuum pump 23, either alone or inconjunction with similar such devices, provides and maintains a vacuumover a selected period of time in at least entrance loadlock 17,reaction chamber 19, and exit loadlock 21.

Entrance loadlock 17 typically includes an entrance actuating member 25for precisely grasping, holding, and moving pre-process wafers 18.Entrance actuating member 25 is usually a pivoting armature locatedwithin entrance loadlock 17. Entrance actuating member 25 is adapted topivot and extend outside of entrance loadlock 17, either through a firstopening 27 to grasp pre-process wafer 18 and move it into entranceloadlock 17, or through a second opening 29 to move pre-process wafer 18out of entrance loadlock 17 and into vacuum reaction chamber 19.Entrance loadlock 17 is in fluid communication with vacuum pump 23, orother similar devices. Thus, entrance loadlock 17 provides a pressurecontrolled environment necessary for a transition from atmosphericpressure to a vacuum, or vice versa.

In a similar fashion, exit loadlock 21 typically includes an exitactuating member 31 for precisely grasping, holding, and movingpost-process wafers. Exit actuating member 31 is usually a pivotingarmature located within exit loadlock 21. Exit actuating member 31 isadapted to pivot and extend outside of exit loadlock 21 either through afirst opening 33 to grasp and remove the post-process wafer from withinreaction chamber 19 and move it into exit loadlock 21, or through asecond opening 35 to move the post-process wafer out of exit loadlock 21for further processing. Exit loadlock 21 is in fluid communication withvacuum pump 23, or other similar devices. Thus, exit loadlock 21provides a pressure controlled environment necessary for a transitionfrom atmospheric pressure to a vacuum, or vice versa.

Reaction chamber 19 is a vacuum chamber in which the plasma etchingprocess takes place. The plasma etching process may involve theapplication of one or more chemical etchants and production of a plasmastate in one or more steps. Various gaseous media are used to performthe etching, depending upon the semiconductor material being etched, thedesired etched profile, and the desired etching rate. In any event, itis generally desirable that a vacuum is maintained within reactionchamber 19 at all times during the plasma etching process.

Continuing with reference to FIG. 1 in the drawings, operation ofprior-art vacuum plasma etching device 11 will now be discussed. First,a cassette (not shown) holding a plurality of semiconductor wafers isloaded into vacuum plasma etching device 11 by a user (not shown). Firstopening 27 of entrance loadlock 17 is opened to the atmosphere so thatentrance actuating member 25 may pivot and extend outside of entranceloadlock 17 to grasp pre-process wafer 18 from the cassette ofsemiconductor wafers, or some other wafer transport device. Whileentrance loadlock 17 is opened to the atmosphere, the pressure withinentrance loadlock 17 is at atmospheric pressure, or the pressure withinvacuum plasma etching device 11, as would be the case if vacuum plasmaetching device 11 is pressure sealed. Entrance actuating member 25grasps pre-process wafer 18 and moves it to a precise location withinentrance loadlock 17. Once pre-process wafer 18 has been moved intoentrance loadlock 17, first opening 27 of entrance loadlock 17 is closedand sealed shut. Once pre-process wafer 18 is sealed within entranceloadlock 17, vacuum pump 23 begins a pump-down process in which air andother gas is pumped out of entrance loadlock 17 until a vacuum iscreated within entrance loadlock 17.

Pre-process wafer 18 is held in the entrance loadlock for apredetermined amount of time, or a “loadlock hold period,” typically atleast sixty seconds, until reaction chamber 19 is ready to receivepre-process wafer 18. When reaction chamber is ready to receivepre-process wafer 18, reaction chamber 19 is opened to entrance loadlock17. Then, entrance actuating member 25 moves pre-process wafer 18 fromwithin entrance loadlock 17 to a precise location within reactionchamber 19. Once pre-process wafer 18 has been properly located withinreaction chamber 19, entrance actuating member 25 retracts out ofreaction chamber 19, and reaction chamber 19 is closed to entranceloadlock 17. It is preferred that pre-process wafer 18 is passed fromentrance loadlock 17 into reaction chamber 19 at a controlled,sub-atmospheric pressure.

Once pre-process wafer 18 is properly located within reaction chamber19, pre-process wafer 18 undergoes the plasma etching process. Asexplained above, the plasma etching process may involve multiple stagesusing multiple gaseous etchants. As mentioned above, the etching processhas a predetermined process cycle, and is performed over a predeterminedprocess cycle time, usually at least sixty seconds. During or near theend of the process cycle, exit loadlock 21 is closed to the atmosphere,and a vacuum is created within exit loadlock 21 by vacuum pump 23, or asimilar pressure control or gas-evacuation device. At the conclusion ofthe plasma etching process, pre-process wafer 18 has become an etched,post-process wafer. Reaction chamber 19 is then opened to exit loadlock21, so that exit actuating member 31 may pivot and extend through firstopening 33 into reaction chamber 19. Exit actuating member 31 grasps thepost-process wafer and moves it from reaction chamber 19 to a preciselocation within exit loadlock 21. Once the post-process wafer and exitactuating member 31 are removed from reaction chamber 19, reactionchamber 19 is closed to exit loadlock 21.

After exit loadlock 21 has been closed and sealed, the vacuum withinexit loadlock 21 is released and the pressure within exit loadlock 21 isadjusted by vacuum pump 23 to a selected level, usually eitheratmospheric pressure, or the pressure within vacuum plasma etchingdevice 11. Once exit loadlock 21 is opened to the atmosphere, exitactuating member 31 moves the post-process wafer out of exit loadlock 21and places the post-process wafer in a cassette (not shown) for holdinga plurality of post-process wafers for further processing, or collectionby the user. Finally, exit actuating member 31 is retracted back withinexit loadlock 21 and exit loadlock 21 is again closed to the atmosphere.

Although the above description is an abbreviation of the entire processfor plasma etching a semiconductor wafer with vacuum plasma etchingdevice 11, it will be apparent that the process cycle defined above issufficient for purposes of the present invention. The steps described inthe process cycle defined above, particularly the steps of creating andmaintaining vacuums within entrance loadlock 17 and exit loadlock 19,generally occur while a semiconductor wafer is being plasma etchedwithin reaction chamber 19. Of particular importance is thepredetermined period of time pre-process wafer 18 is held idly in avacuum within entrance loadlock 17. For purposes of the presentinvention, this predetermined period of time will be referred to as the“loadlock idle period.” It should be understood that the entire vacuumplasma etching process is controlled by microprocessors and othercontrol circuitry.

Referring now to FIG. 2 in the drawings, prior-art entrance loadlock 17is illustrated in an exploded perspective view. Entrance actuatingmember 25 is shown to include a rotating base portion 25 a and ahorseshoe-shaped portion 25 b that pivots about an end of base portion25 a. Horseshoe-shaped portion 25 b includes conventional means 25 c forgrasping, holding, and precisely locating pre-process wafers 18. It isimportant to note that entrance actuating member 25 is adapted to grasppre-process wafer 18 from an underneath side, such that an entire uppersurface of pre-process wafer 18 is unobstructed. As is shown, firstopening 27 and second opening 29 are located 90° apart on adjacent sidesof entrance loadlock 17. It should be understood that entrance loadlock17 may have openings disposed at various locations on entrance loadlock17 without affecting the operation of the present invention. As isshown, entrance loadlock 17 includes many components: mechanisms foropening, closing, and sealing first opening 27 and second opening 29,mechanisms for actuating entrance actuating member 25, and couplingdevices for coupling vacuum pump 23 to entrance loadlock 17. Ofparticular importance is cover 51. Cover 51 is typically made of a sheetof rigid plastic and is releasably fastened to a body portion 5 ofentrance loadlock 17 by fastening means 55, typically a plurality ofscrews. It is necessary that cover 51 be made of a material rigid enoughto withstand the vacuum created within entrance loadlock 17. Cover 51 ofprior-art entrance loadlock 17 is generally transparent and serves tosealingly enclose entrance loadlock 17. Cover 51 is transparent so thata user may observe and diagnose handling problems without openingloadlock 17.

Referring now to FIGS. 3 and 4 in the drawings, an improved vacuumloadlock 61 according to the present invention is illustrated. A typicaluse for vacuum loadlock 61 would be as a substitute for entranceloadlock 17 in vacuum plasma etching device 11 described above. As isshown, cover 51 has been replaced by a cover 63, preferably a lexancover. Cover 63 includes an annular aperture 64, preferably concentricabout pre-process wafer 18. An annular collar 65 is sealingly coupled tocover 63. A window member 67 is sealingly coupled to collar 65,preferably by an 0-ring. Collar 65 may provide additional means ofadapting and sealingly coupling window member 67 cover 63. Window member67 is preferably made of a material that is transparent to ultravioletlight, such as quartz or sapphire. It should be understood that otherultraviolet-transparent materials may be used. Further, it should beunderstood that entire cover 63 may be made of suchultraviolet-transparent material; however, due to economicconsiderations, the use of window member 67 is preferred. Vacuumloadlock 61 may have a plurality of openings through which wafers aremoved, and that the openings may be located at various locations aroundvacuum loadlock 61 without affecting the operation of vacuum loadlock61.

A lamp housing 69 is carried by vacuum loadlock 61. Lamp housing 69includes a source of ultraviolet light 71, such as an ultraviolet lamp.Source of ultraviolet light 71 may be either a lamp array or an opticalassembly of lenses. The primary purpose of source of ultraviolet light71 is to produce a relatively uniform illumination or heating ofpre-process wafer 18, particularly the photo-resist pattern on uppersurface 18 a. Lamp housing 69 and source of ultraviolet lamp 71 areconfigured such that rays of ultraviolet light 73 pass through lamphousing 69, window member 67, collar 65, aperture 64, and cover 63,thereby impinging upon upper surface 18 a of pre-process wafer 18containing the photo-resist pattern. Pre-process wafer 18 is held withinvacuum loadlock 61 by an entrance actuating arm 25′. Entrance actuatingarm 25′ is very similar in form and function as prior-art entranceactuating arm 25. Thus, entrance actuating arm 25′ includes a rotatingbase portion 25 a′ and a horseshoe-shaped portion 25 b′ that pivotsabout an end of base portion 25 a′. Horseshoe-shaped portion 25 b′includes conventional means 25 c′ for grasping, holding, and preciselylocating pre-process wafers 18. It is important to note that entranceactuating member 25′ is adapted to grasp pre-process wafer 18 from lowersurface 18 b, such that an entire upper surface 18 a of pre-processwafer 18 is unobstructed. As mentioned above, the photo-resist patternis contained in upper surface 18 a.

The improved vacuum plasma etching device according to the presentinvention, including vacuum loadlock 61, is operated in the same generalmanner described above for the prior-art vacuum plasma etching device 11shown in FIG. 1. The primary difference in the operation of prior-artvacuum plasma etching device 11 and the improved vacuum plasma etchingdevice of the present invention, is that the present invention includessource of ultraviolet light 71. By adding source of ultraviolet light 71to vacuum loadlock 61, the vacuum plasma etching device of the presentinvention is capable of performing an additional operation ofselectively exposing pre-process wafer 18 to an ultraviolet bake inwhich the photo-resist is hardened, or cured. This ultraviolet-lightcuring process makes the photo-resist pattern more resistant to theplasma etch and helps preserve the pattern integrity during the plasmaetching process. The control parameters of source of ultraviolet light71, such as turning on, duration of staying on, intensity of theultraviolet light, and turning off, are preferably integrated into userinterface panel 15.

The presence of a vacuum during the ultraviolet curing process helps toremove volatile substances present in the photo-resist, thereby furtherhardening the photo-resist against the plasma etching process. Curingthe photo-resist pattern with ultraviolet light improves CD dispersion,enhances pattern transfer, and prevents photo-resist reticulation. Theultraviolet-light curing process preferably consists of selectivelyexposing the photo-resist pattern to ultraviolet light at a selectedintensity for a selected period of time, or “exposure period,” toproduce the desired level of photo resist cross linking. It is desirablethat the exposure period be less than or equal to the loadlock idleperiod. Because this curing process should be performed prior to theplasma etching process, it is preferred that the curing process takeplace during the loadlock idle period while pre-process wafer 18 is heldin a vacuum within vacuum loadlock 61. In addition, it is advantageousto perform the ultraviolet-light curing process in a vacuum, because avacuum helps to remove volatile substances present in the photo-resistpattern, thereby further hardening the photo-resist pattern against theetching process. Thus, this additional ultraviolet curing processavailable with the vacuum plasma etching device of the present inventioneliminates the need for additional devices in which to perform thecuring process, and eliminates the manufacturing time associated withloading, unloading, and transferring pre-process wafers 18 betweendevices.

Although the above-described preferred embodiment of the presentinvention involves selectively exposing the photo-resist pattern toultraviolet light, it should be understood that other sources ofradiation may be employed to irradiate the photo-resist pattern. In suchinstances, cover 51 would, of course, be adapted to allow such radiationto impinge upon the photo-resist pattern. In addition, although thepredetermined loadlock idle period would not change, the selectedexposure periods for other forms of radiation may vary.

It will be apparent that the present invention may be implemented byconverting an existing vacuum plasma etching device, such as device 11,by either replacing entrance loadlock 17 with improved vacuum loadlock61, or by simply replacing cover 51 with cover 63 and the associatedcomponents described above. In addition, it should be apparent from theforegoing that an invention having significant advantages has beenprovided. While the invention is shown in only one of its forms, and hasbeen particularly shown and described with reference to a preferredembodiment, it will be understood by those skilled in the art thatvarious changes in form and detail may be made therein without departingfrom the spirit and scope of the invention.

What is claimed is:
 1. A vacuum plasma etching device for plasma etchinga semiconductor wafer having a photo-resist pattern, comprising: atleast one vacuum loadlock loading the semiconductor wafer into thevacuum plasma etching device; a source of ultraviolet radiationselectively irradiating the photo-resist pattern with incident radiationwhile the semiconductor wafer is held within the at least one vacuumloadlock.
 2. The vacuum plasma etching device according to claim 1,wherein the source of radiation is a source of ultraviolet light locatedoutside the at least one vacuum loadlock, and the incident radiation isultraviolet light.
 3. The vacuum plasma etching device according toclaim 1, wherein the semiconductor wafer is held in a vacuum within theat least one vacuum loadlock for a predetermined loadlock idle period,and wherein the photo-resist pattern is selectively irradiated for aselected exposure period, the selected exposure period being equal to orless than the predetermined loadlock idle period.
 4. The vacuum plasmaetching device according to claim 3, wherein the selected exposureperiod is less than about 60 seconds.
 5. A vacuum plasma etching devicefor plasma etching a semiconductor wafer having a photo-resist pattern,comprising: a vacuum reaction chamber for performing plasma etching; atleast one vacuum loadlock in communication with the vacuum reactionchamber, the at least one vacuum loadlock being adapted to transitionfrom a vacuum to a non-vacuum and vice-versa and for loading thesemiconductor wafer into the vacuum reaction chamber; a vacuum pumpmeans for selectively creating and maintaining a vacuum within thevacuum reaction change and the at least one vacuum loadlock; a controlsystem for controlling an operation of the vacuum plasma etching device;and a source of ultraviolet light for selectively irradiating thephoto-resist pattern with ultraviolet light while the semiconductorwafer is held within the at least one vacuum loadlock.
 6. The vacuumplasma etching device according to claim 5, wherein the at least onevacuum loadlock is adapted to hold the semiconductor wafer such that thephoto-resist pattern is selectively exposed to the ultraviolet light. 7.The vacuum plasma etching device according to claim 6, wherein the atleast one vacuum loadlock is further adapted to hold the semiconductorwafer such that the photo-resist pattern is selectively exposed to theultraviolet light while in a vacuum.
 8. The vacuum plasma etching deviceaccording to claim 5, wherein the at least one vacuum loadlockcomprises: a vacuum-sealable housing; an actuating member fortransporting and holding the semiconductor wafer into and out of the atleast one vacuum loadlock, the actuating member being at least partiallydisposed within the at least on vacuum loadlock; at least one opening inthe vacuum-sealable housing through which the actuating membertransports the semiconductor wafer, wherein the vacuum-sealable housinghas an ultraviolet light-transparent portion through which theultraviolet light from the ultraviolet light source passes to impingeupon the photo-resist pattern.
 9. The vacuum plasma etching deviceaccording to claim 8, wherein the ultraviolet light-transparent portionis a window in a top cover sealingly coupled to the vacuum-sealablehousing.
 10. The vacuum plasma etching device according to claim 8,wherein the ultraviolet light-transparent portion is a top coversealingly coupled to the vacuum-sealable housing.
 11. The vacuum plasmaetching device according to claim 8, wherein the ultravioletlight-transparent portion is made of quartz.
 12. The vacuum plasmaetching device according to claim 8, wherein the ultravioletlight-transparent portion is made of sapphire.
 13. The vacuum plasmaetching device according to claim 5, wherein the source of ultravioletlight comprises: a lamp housing coupled to the at least one vacuumloadlock; and at least one ultraviolet lamp carried by the lamp housing.14. The vacuum plasma etching device according to claim 13, wherein thesource of ultraviolet light comprises: an arrangement of optical lensesfor focusing and intensifying the impingement of the ultraviolet lightupon the photo-resist pattern.
 15. A vacuum loadlock for use in a vacuumplasma etching device for etching a semiconductor wafer having aphoto-resist pattern defining where a plasma will etch the semiconductorwafer, comprising: a housing having a bottom portion, a plurality ofside portions, and an initially open top portion; a plurality ofopenings in the side portions, the plurality of openings beingconfigured to allow the semiconductor wafer to pass therethrough to beloaded into the vacuum plasma etching device; a plurality of sealingmeans for releasably vacuum-sealing the plurality of openings; anactuating means for moving the semiconductor wafer through the pluralityof openings, and for locating the semiconductor wafer within thehousing; a vacuum pump means for selectively creating and maintaining avacuum within the housing; a cover member for sealingly closing theinitially open top portion, the cover member having an ultravioletlight-transparent portion; a source of ultraviolet light for generatingultraviolet light, the source of ultraviolet light being coupled to thecover member such that the ultraviolet light passes through theultraviolet light-transparent portion and impinges upon the photo-resistpattern; and a control system for controlling the sealing means, theactuating means, the vacuum pump means, and the source of ultravioletlight.
 16. The vacuum loadlock according to claim 15, wherein theultraviolet light-transparent portion is made of quartz.
 17. The vacuumloadlock according to claim 15, wherein the ultravioletlight-transparent portion is made of sapphire.
 18. The vacuum loadlockaccording to claim 15, wherein the ultraviolet light-transparent portionis circular in shape and located within the cover member such that theultraviolet light-transparent portion is concentric with thesemiconductor wafer.
 19. The vacuum loadlock according to claim 15,wherein the ultraviolet light cures the photo-resist pattern.